High rep rate high performance plasma focus as a powerful radiation source

Lee, Paul; Lee, P.; Zhang, Guixin; Feng, Xiaohua; Грибков, В. А.; Liu, Mahe; Şerban, Adrian; Wong, Terence Kin Shun

doi:10.1109/27.725141

Cited by 175 publications

(57 citation statements)

References 12 publications

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“…[3][4][5][6][7][8][9]. A most comprehensive review of the state of the art can be found in Bernard et al 10 The approach followed in the present work is to use the electron beam generated backward by the Plasma Focus device to generate xrays upon conversion of the beam onto a metal target.…”

mentioning

confidence: 99%

EBT2 dosimetry of x-rays produced by the electron beam from a Plasma Focus for medical applications

Ceccolini

Rocchi

Mostacci

et al. 2012

Journal of Applied Physics

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The electron beam emitted from the back of Plasma Focus devices is being studied as a radiation source for IORT (IntraOperative Radiation Therapy) applications. A Plasma Focus device is being developed to this aim, to be utilized as an X-ray source. The electron beam is driven to impinge on 50 µm brass foil, where conversion X-rays are generated. Measurements with gafchromic film are performed to analyse the attenuation of the X-rays beam and to predict the dose given to the culture cell in radiobiological experiments to follow.

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mentioning

confidence: 99%

EBT2 dosimetry of x-rays produced by the electron beam from a Plasma Focus for medical applications

Ceccolini

Rocchi

Mostacci

et al. 2012

Journal of Applied Physics

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“…6,7,10,11,[14][15][16] An improved five-phase code crucially incorporating small disturbance speed, 17 and radiation coupling with dynamics, assisted further projects, 8,[18][19][20][21][22][23] and was published in the internet in 2000 ͑Ref. The basic model was described in 1984 ͑Ref.…”

mentioning

confidence: 99%

“…The basic model was described in 1984 ͑Ref. It has been used in machines including UNU/ICTP PFF, 10,11,15,16,21 NX2, [18][19][20] and NX1, 18 and has been adapted to the Filippovtype DENA. 6,7,10,11,[14][15][16] An improved five-phase code crucially incorporating small disturbance speed, 17 and radiation coupling with dynamics, assisted further projects, 8,[18][19][20][21][22][23] and was published in the internet in 2000 ͑Ref.…”

mentioning

confidence: 99%

Computing plasma focus pinch current from total current measurement

Lee

Saw

Rawat

et al. 2008

Applied Physics Letters

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The total current I total waveform in a plasma focus discharge is the most commonly measured quantity, contrasting with the difficult measurement of I pinch . However, yield laws should be scaled to focus pinch current I pinch rather than the peak I total . This paper describes how I pinch may be computed from the I total trace by fitting a computed current trace to the measured current trace using the Lee model. The method is applied to an experiment in which both the I total trace and the plasma sheath current trace were measured. The result shows good agreement between the values of computed and measured I pinch .

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“…16) and used in the design and interpretation of experiments. [17][18][19] An improved 5-phase code 2 incorporating finite small disturbance speed, 20 radiation and radiation-coupled dynamics was used, [21][22][23] and was web-published 24 in 2000. Plasma self-absorption was included 24 in 2007.…”

Section: The Lee Model Codementioning

confidence: 99%

Plasma focus ion beam fluence and flux—For various gases

Lee

Saw

2013

Physics of Plasmas

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A recent paper derived benchmarks for deuteron beam fluence and flux in a plasma focus (PF) [S. Lee and S. H. Saw, Phys. Plasmas 19, 112703 (2012)]. In the present work we start from first principles, derive the flux equation of the ion beam of any gas; link to the Lee Model code and hence compute the ion beam properties of the PF. The results show that, for a given PF, the fluence, flux, ion number and ion current decrease from the lightest to the heaviest gas except for trend-breaking higher values for Ar fluence and flux. The energy fluence, energy flux, power flow, and damage factors are relatively constant from H2 to N2 but increase for Ne, Ar, Kr and Xe due to radiative cooling and collapse effects. This paper provides much needed benchmark reference values and scaling trends for ion beams of a PF operated in any gas.

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High rep rate high performance plasma focus as a powerful radiation source

Cited by 175 publications

References 12 publications

EBT2 dosimetry of x-rays produced by the electron beam from a Plasma Focus for medical applications

EBT2 dosimetry of x-rays produced by the electron beam from a Plasma Focus for medical applications

Computing plasma focus pinch current from total current measurement

Plasma focus ion beam fluence and flux—For various gases

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